ATP Drives Efficient Terpene Biosynthesis in Marine Thraustochytrids
Aiqing Zhang, Kaya Mernitz, Chao Wu, Wei Xiong, Yaodong He, Guangyi Wang, Xin Wang
Abstract
Terpenoids are a large class of lipid molecules with important biological functions and diverse industrial and medicinal applications. Metabolic engineering for terpene production has been hindered by the low-flux distribution to its biosynthesis pathway. In practice, a high substrate load is generally required to reach high product titers. Here, we show that mevalonate-derived terpene biosynthesis is constrained by local pathway thermodynamics, which can only be partially relieved by increasing substrate levels. Through comparative omics and biochemical analyses, we discovered a unique mechanism for high terpene accumulation in marine protist thraustochytrids. Through a sodium-induced mechanism, thraustochytrids shift their energy metabolism from carbohydrate to lipid oxidation for enhanced ATP production, providing a strong thermodynamic driving force for efficient terpene biosynthesis. This study reveals an important mechanism in eukaryotes to overcome the thermodynamic constraint in low-flux pathways by increased ATP consumption. Engineering energy metabolism thus provides an important alternative to relieve flux constraints in low-flux and energy-consuming pathways.